JP2005025818A - Signal processor, its method, and computer - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a signal processor capable of deciding the validity of a content signal and whether the content signal is appropriately reproduced or not. <P>SOLUTION: A recording disk DISK is set in a computer 3 and a drive 3 of the computer 3 outputs the content signal CONT 1 read out of the recording disk DISK through a bus 11 to a reproducing section 6. The reproducing section 6 reproduces the content signal CONT 1, generates a reproduction signal S 6 and outputs the signal through a signal line 10 to the drive 7. The drive 7 generates a noise signal based on the seed data SEED and key data K_EN read out of the recording disk DISK, detects the correlation between the noise signal and the reproduction signal S 6 and decides that the content signal CONT 1 is valid and that the content signal CONT 1 outputted from the drive 7 is reproduced when the correlation exceeds the prescribed level. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a signal processing apparatus, method and computer for adding a copyright protection signal to a content signal.
[0002]
[Prior art]
Conventionally, there is a digital watermark (watermark) as a technique for protecting the copyright of content such as video and audio.
This digital watermark technology adds digital watermark information to a content signal by changing the frequency component of the content signal according to a predetermined rule.
At the time of detection, the electronic watermark information added to the content signal is detected based on the above rule, and the outflow source of the content signal is specified based on the result.
The attack resistance of the digital watermark technique is based on the premise that the above rule for adding digital watermark information to a content signal is kept secret.
In addition, as techniques for protecting copyright, other techniques using encryption such as CSS (Content Scrambling System), CPRM (Content Protection for Recordable Media), and CPPM are known.
The above-described copyright protection technology is to check the validity of a content signal by detecting digital watermark information or decrypting a cipher when reproducing the content signal. That is, these copyright protection functions work only after the content signal is reproduced.
Such copyright protection technology is based on the premise that the manufacturer of the playback device manages the security of processing in the playback device.
[0003]
[Problems to be solved by the invention]
The content signal described above may be reproduced by a computer such as a personal computer in addition to the reproduction apparatus described above.
Such a computer can operate various programs in addition to the content signal reproduction program, and it is difficult for the manufacturer to manage the entire processing.
In recent years, illegal activities such as copying illegally ripping and distributing content signals recorded on discs such as DVDs have been frequently performed by utilizing the characteristics of computers to execute illegal copy programs on computers. ing. Ripping is, for example, a process of extracting audio data in a digital format recorded on a music CD (Compact Disk), converting it into a file format that can be processed by a computer, and storing it.
Such a program for illegal copying intentionally creates a state in which the above-described copyright protection technology does not function without reproducing the content signal.
For example, an illegal copy program such as SmartRipper that extracts and reproduces the original MPEG content by solving CSS.
Such a program does not perform content signal reproduction processing as described above, and does not activate an application for copyright protection. Therefore, all copyright protection technology functions stop.
Since a drive such as a computer cannot distinguish between ripping processing by such a program and playback processing by a regular playback program, the content signal is read out from the recording disk and output, and as a result, illegal copying of the content signal can be easily performed. Will be done.
[0004]
The present invention has been made in view of the above-described prior art, and an object of the present invention is to provide a signal processing apparatus, a method thereof, and a computer that can determine the validity of a content signal and whether or not the content signal has been properly reproduced.
[0005]
[Means for Solving the Problems]
In order to achieve the above-described object, a signal processing device according to a first aspect of the present invention includes an output unit that outputs a provided content signal, an input unit that inputs a signal, and an acquisition unit that acquires a parameter in a secure state. And a characteristic defined according to the parameter acquired by the acquisition unit, and a characteristic that a reproduction signal obtained by reproducing the content signal when the content signal output by the output unit is valid should have Determining means for determining whether or not the signal inputted by the input means has.
[0006]
The operation of the signal processing apparatus of the first invention is as follows.
The output means outputs the provided content signal to the outside of the signal processing apparatus.
And an input means inputs a signal from the exterior of the said signal processing apparatus.
Further, the acquisition unit acquires the parameter in a secure state.
A reproduction signal obtained by reproducing the content signal when the determination unit has a characteristic defined according to the parameter acquired by the acquisition unit and the content signal output by the output unit is valid It is determined whether or not the signal input by the input means has the characteristic that should be possessed.
[0007]
According to a second aspect of the present invention, there is provided a computer for receiving a content signal, a reproducing unit for reproducing the content signal to generate a reproduction signal, or a mounting unit for mounting the reproducing unit, and a process for executing a predetermined program. The receiving means includes an output means for outputting the provided content signal to the reproduction means, an input means for inputting the reproduction signal from the reproduction means, and a parameter in a secure state. And a reproduction characteristic obtained by reproducing the content signal when the content signal output by the output means is valid, the characteristic being defined according to the parameter acquired by the acquisition means A determination method for determining whether or not the reproduction signal input by the input means has a characteristic that the signal should have. With the door.
[0008]
The operation of the computer of the second invention is as follows.
The output means of the receiving means outputs the received content signal to the reproducing means.
Then, the reproduction means reproduces the input content signal to generate a reproduction signal, and outputs this to the input means of the receiving means.
The acquisition unit of the receiving unit acquires the parameter in a secure state.
When the determination unit of the receiving unit has characteristics defined according to the parameter acquired by the acquiring unit and the content signal output by the output unit is valid, it is obtained by reproducing the content signal. It is determined whether or not the reproduction signal input by the input means has a characteristic that the reproduced signal should have.
[0009]
According to a third aspect of the present invention, there is provided a reproduction means for reproducing a content signal to generate a reproduction signal or an attachment means for attaching the reproduction means, and a characteristic defined according to a predetermined parameter, wherein the content signal is A determination means for determining whether or not the reproduction signal input from the reproduction means has characteristics to be possessed by the reproduction signal obtained by reproducing the content signal when it is valid; and receiving the content signal Receiving means for outputting the content signal to the reproducing means, receiving a predetermined parameter in a secure state, and outputting the parameter to the determining means.
[0010]
The operation of the computer of the third invention is as follows.
The receiving means receives the content signal and outputs it to the reproducing means.
The receiving unit receives a predetermined parameter in a secure state and outputs the parameter to the determining unit.
Then, the reproduction means reproduces the content signal input from the receiving means to generate a reproduction signal, and outputs this to the determination means.
Then, the determination means determines the characteristics that should be possessed by the reproduction signal obtained by reproducing the content signal when the content signal is valid, from the reproduction means. It is determined whether or not the input reproduction signal has.
[0011]
A signal processing method according to a fourth aspect of the present invention is a signal processing method executed by a signal processing device, the first step of outputting the provided content signal to the outside of the signal processing device, and the signal processing device A second step of inputting a signal from the outside; a third step of acquiring a parameter in a secure state; and a characteristic defined according to the parameter acquired in the third step, wherein the first step When the content signal output in step (2) is valid, it is determined whether or not the signal input in the second step has characteristics that the playback signal obtained by reproducing the content signal should have. And a fourth step.
[0012]
According to a fifth aspect of the present invention, there is provided a signal processing method in which the content providing device generates a content signal having characteristics according to a predetermined parameter, and the content providing device transmits the parameter to the computer in a secure state. A second step of providing the computer with the content signal generated in the first step, and a third step of reproducing the content signal received by the computer in the second step; A characteristic defined by the computer according to the parameter received in the second step, and a characteristic that a reproduction signal obtained by reproducing the content signal when the content signal is valid should have And a fifth step of determining whether or not the signal obtained by the reproduction of the third step has.
[0013]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, a signal processing system according to an embodiment of the present invention will be described.
First embodiment
FIG. 1 is an overall configuration diagram of a signal processing system 1 according to the present embodiment.
As shown in FIG. 1, the signal processing system 1 includes, for example, a content providing device 2 and a computer 3.
In FIG. 1, a drive 7 corresponds to the signal processing devices of the first and fourth inventions and the receiving means of the second invention.
The computer 3 corresponds to the computers of the second and fifth inventions, the CPU 4 corresponds to the processing means of the second invention, and the reproducing unit 6 corresponds to the reproducing means of the second invention.
[0014]
First, the outline of the signal processing system 1 will be described.
In the signal processing system 1, the content providing apparatus 2 generates the content signal CONT1 to which the noise signal NOISE1 generated based on the specified seed data SEED and key data K_EN which are predetermined parameters is added. Also, digital watermark information for copyright protection detected at the time of reproduction is added to the content signal CONT1.
Then, the content providing device 2 records the seed data SEED and the key data K_EN in a secure state on the recording disk DISK, and records the content signal CONT1 on a recording disk DISK such as an optical disk or a magnetic disk.
Then, the recording disk DISK is set in the computer 3, and the drive 7 of the computer 3 outputs the content signal CONT 1 (content signal of the present invention) read from the recording disk DISK to the reproducing unit 6 via the bus 11.
Then, the reproduction unit 6 reproduces the content signal CONT1 to generate a reproduction signal S6 and outputs it to the drive 7 via the signal line 10.
The drive 7 generates a noise signal based on the seed data SEED and the key data K_EN read from the recording disk DISK, detects the correlation between the noise signal and the reproduction signal S6, and the correlation exceeds a predetermined level. In this case, it is determined that the content signal CONT1 is valid and the content signal CONT1 output from the drive 7 has been reproduced.
In the signal processing system 1, if the content signal CONT 1 output from the drive 7 is not output to the playback unit 6 and a state in which playback is not performed is intentionally made and an illegal copy 0 is performed, the above correlation is generated in the drive 7. Below a certain level. Therefore, the output of the content signal CONT1 from the drive 7 is stopped.
Further, when the recording disk DISK records the content signal CONT1 illegally, the correlation is below a predetermined level in the drive 7 because the parameter is not recorded on the recording disk DISK. Therefore, similarly, the output of the content signal CONT1 from the drive 7 is stopped.
[0015]
[Content providing device 2]
The content providing device 2 generates a content signal CONT1 to which a noise signal NOISE1 generated based on specified seed data SEED and key data K_EN which are predetermined parameters is added.
In the present embodiment, at least one of the seed data SEED and the key data K_EN has a value unique to the recording disk DISK or the content signal CONT1. Therefore, the noise signal NOISE1 is also a unique signal.
The content signal CONT1 is, for example, a video signal or an audio signal, and the content providing apparatus 2 is for copy control such as a video watermark (VWM) or an audio watermark (AWM) for protecting the copyright of the content signal CONT1. Is added (embedded) to the content signal CONT1.
For example, the content providing apparatus 2 adds a predetermined change (modulation) to the frequency component of the content signal CONT1 in a secret manner, thereby adding the above-described digital watermark information for copy control to the content signal CONT1. Append.
Then, the content providing apparatus 2 records the content signal CONT1 on the recording disk DISK, and records the seed data SEED and the key data K_EN in a secure area in the recording disk DISK.
Here, the secure area in the recording disk DISK is, for example, an area that can be read only by a drive to which a predetermined authority is given.
Note that the content providing device 2 uses, as necessary, the above-mentioned copyright protection such as a CSS (Content Scrabbling System) for copy protection of DVD (Digital Versatile Disk) and a CPRM (Content Protection for Recordable Media) encryption. It may be applied to the content signal CONT1.
The above-described copy control digital watermark information and encryption for copyright protection are detected by a predetermined detection device at the time of reproduction of the content signal CONT1 and used for various processes for copyright protection.
[0016]
[Computer 3]
The computer 3 is a personal computer, for example.
As shown in FIG. 1, the computer 3 includes, for example, a CPU 4 (Central Processing Unit), a memory 5, a playback unit 6, and a drive 7, which are connected via a bus 11.
The CPU 4 executes a predetermined program and comprehensively controls the processing of the computer 3.
The memory 5 stores various data necessary for the CPU 4 to execute the program.
[0017]
The reproduction unit 6 alone or in cooperation with the CPU 4 performs a reproduction process such as decoding (decoding) and expansion of the content signal input from the drive 7 to generate a reproduction signal S6.
The playback unit 6 is realized by, for example, an electronic circuit on a board mounted in a slot (the mounting unit of the present invention) of the computer 3, a video card, or an application program executed by the CPU 4.
For example, the reproducing unit 6 outputs a reproduction signal S6 to the drive 7 via the signal line 10. The reproduction signal S6 includes, for example, a video signal, an audio signal, copy control digital watermark information, a noise signal, and a control signal that constitute the content signal CONT1.
The output of the reproduction signal S6 from the reproduction unit 6 to the drive 7 via the signal line 10 is, for example, IDE (Integrated Device Electronics), SCSI (Small Computer System Interface), Serial ATA (AT attachment), USB (Us us) , IEEE (Institute of Electrical and Electronics Engineers) 1394 or a dedicated line such as video and audio.
For example, the signal line 10 is provided separately from the bus 11.
[0018]
When the reproduction unit 6 is realized by a video card, for example, a terminal for connecting the signal line 10 is provided on the video card. In this case, there is a method of using RGB signals as they are. However, if the load on the detection side for adapting to changes in the resolution of the PC monitor or the like increases, the amount of calculation for correlation detection increases. In order to improve this, the video card has a function of converting into a broadcast format such as NTSC (National Television System Committee) or PAL (Phase Alternation by Line), and the converted signal is used as a reproduction signal S6. It may be output to the drive 7 via the line 10. Thereby, the resolution and the refresh frequency of the reproduction signal S6 can be made constant irrespective of the RGB signals obtained by the processing by the CPU 4, so that the processing using the reproduction signal S6 by the drive 7 can be simplified.
[0019]
Note that the reproduction signal S6 may be output from the reproduction unit 6 to the drive 7 using the bus 11 instead of the signal line 10. In this case, the reproduction signal S6 is output from the reproduction unit 6 to the drive 7 at a predetermined timing assigned in time division on the bus 11. In this case, the reproduction signal S6 is expanded in the reproduction unit 6, the amount of data is very large, and there is a possibility that the bus occupation rate due to transmission of the reproduction signal S6 becomes high. Therefore, the reproduction unit 6 performs predetermined scaling on the reproduction signal S6 to reduce the amount of data, and then outputs the data to the drive 7 via the bus 11. The reproduction unit 6 has, for example, a 720 × 480 pixel in a DVD or the like. However, when a correlation due to noise is used, the reproduction signal S6 is subjected to the above-described scaling that converts this to a low resolution, such as 360 × 240, thereby obtaining a color signal. The calculation amount for determination can be reduced by using only the luminance signal without using it.
Further, the playback unit 6 uses the playback signal S6 described above or in the process of generating the playback signal S6, the process related to copyright protection based on the above-described digital watermark information for copy control, and the above-described processing. The processing related to copyright protection based on encryption such as CSS and CPRM.
[0020]
The drive 7 reads the content signal CONT1 from the recording disk DISK described above and outputs it to the memory 5 via the bus 11.
FIG. 2 is a block diagram of the drive 7 shown in FIG.
As illustrated in FIG. 2, the drive 7 includes, for example, a disk reading unit 21, an output unit 22, a noise generation unit 23, a noise filter 24, an input unit 26, a determination unit 27, and a control unit 28.
Here, the disk reading unit 21 corresponds to the acquisition means of the first and second inventions, the output unit 22 corresponds to the output means of the first and second inventions, the noise generation unit 23, the noise filter 24 and the determination. Means 27 corresponds to the determination means of the first and second inventions, input unit 26 corresponds to the input means of the first and second inventions, and control unit 28 corresponds to the control means of the first invention. Yes.
For example, the noise generation unit 23, the noise filter 24, the superposition unit 25, the determination unit 27, and the control unit 28 are provided in a secure module that cannot monitor and tamper with the internal processing and data of the drive 7 from the outside. Yes.
[0021]
The disk reading unit 21 outputs the seed data SEED and key data K_EN read from the recording disk DISK manufactured by the content providing device 2 to the noise generation unit 23.
Further, the disk reading unit 21 outputs the content signal CONT1 read from the recording disk DISK to the output unit 22.
The output unit 22 outputs the content signal CONT1 to the memory 5 via the bus 11.
[0022]
The noise generator 23 generates a random number based on the seed data SEED input from the disk reader 21. The noise generator 13 encrypts the random number based on the encryption key data K_EN input from the disk reader 21 to generate a noise signal NOISE 2 and outputs the noise signal NOISE 2 to the noise filter 24.
[0023]
FIG. 3 is a block diagram of the noise generator 23 shown in FIG.
As illustrated in FIG. 3, the noise generation unit 23 includes, for example, a PN (Psuedo-Random Number) generation unit 31, a multiplication unit 32, a PN generation unit 33, and an encryption unit 34.
The PN generation unit 31 generates a random number S31 based on the seed data SEED input from the disk reading unit 21, and outputs this to the multiplication unit 32.
The PN generation unit 33 generates a random number S33 independently of the PN generation unit 31 and outputs the random number S33 to the multiplication unit 32.
The multiplication unit 32 multiplies (multiplies) the random number S31 from the PN generation unit 31 and the random number S33 from the PN generation unit 33 to generate a noise signal NOISE3 (Gold code), and outputs this to the encryption unit 34. To do.
Here, if the phase of the random number S31 generated by the PN generation unit 31 is shifted, the number of different noise signals NOISE3 equivalent to the cycle of the random number S31 can be generated. Therefore, by controlling the seed data SEED designated by the PN generation unit 31, a random and various noise signal NOISE3 can be generated.
In this case, by shifting the phase of the random number 31, a plurality of different noise signals NOISE3, which are random numbers generated by the multiplication unit 32, have a large Hamming distance, and detection (determination) errors are less likely to occur.
[0024]
The encryption unit 34 generates the noise signal NOISE2 by encrypting the noise signal NOISE3 input from the multiplication unit 32 based on the key data K_EN input from the PN generation unit 31, and supplies the noise signal NOISE2 to the noise filter 14 illustrated in FIG. Output.
For example, the encryption unit 34 performs scrambling by encryption such as DES (Data Encryption Standard), Triple DES, or AES. Thereby, the noise signal NOISE2 obtained by diffusing the noise signal NOISE3 can be generated.
The noise signal NOISE2 is defined by tap position information and phase shift information (defined by seed data SEED or the like) of the PN code in the PN generation units 31 and 33, and key data K_EN.
[0025]
The noise filter 24 performs a filtering process on the noise signal NOISE 2 input from the noise generation unit 23 to generate a noise signal NOISE 4, and outputs this to the determination unit 27.
In the present embodiment, when the recording disk DISK is manufactured by the content providing apparatus 2 in a valid process, the noise signal NOISE4 generated by the noise filter 24 and the noise signal NOISE1 superimposed on the content signal CONT1 are used. Is the same.
[0026]
The input unit 26 outputs the reproduction signal S6 input from the reproduction unit 6 to the determination unit 27 via the signal line 10.
[0027]
The determination unit 27 detects the correlation between the noise signal NOISE4 from the noise filter 24 and the reproduction signal S6 input from the input unit 26 by the correlation detector 39, and when the correlation is detected at a predetermined level or higher, the content signal It is determined that CONT1 is valid (the recording disc DISK is obtained from a regular route) and the content signal CONT1 is properly reproduced. Otherwise, the content signal CONT1 is invalid or appropriate. It is determined that it has not been played back (there is a possibility that unauthorized copy processing may have been performed).
The determination unit 27 outputs a determination signal S27 indicating the determination result to the control unit 28.
Here, as described above, when the recording disk DISK is manufactured by the content providing apparatus 2 in a proper process and the content signal CONT1 is appropriately reproduced, the noise signal NOISE4 generated by the noise filter 24 is generated. And the reproduction signal S6 are equal to or higher than the predetermined level.
On the other hand, when the recording disk DISK is not manufactured by the content providing apparatus 2 in a proper process or when the content signal CONT1 is not reproduced and the illegal copy is performed, the above-described noise filter 24 generates Unlike the noise signal NOISE4 and the noise signal NOISE1 superimposed on the content signal CONT1, the correlation between the noise signal NOISE4 and the reproduction signal S6 is less than the predetermined level.
[0028]
The detection of the correlation by the determination unit 27 described above is performed, for example, for each field or frame of the reproduction signal S6. Further, the determination unit 27 may detect the correlation of the result obtained by accumulating the result obtained in the field or frame unit for a certain time in the reproduction signal S6.
The determination unit 27 detects the correlation in the field or frame unit of the reproduction signal S6 for the entire field or frame.
For example, when the content signal CONT1 is encoded by the Moving Picture Experts Group (MPEG) 2 method, the determination unit 27 targets the region when the noise signal NOISE1 is added to the signal of 720 × 480 pixels. The above-described correlation is detected.
Thereby, it is possible to effectively suppress an illegal act (spoofing) such as separating the area and using it for another content signal.
Further, when the noise signal NOISE1 is added to the area where the synchronization signal is provided in the content signal CONT1, the determination unit 27 detects the correlation for the area. Thus, when a standardized copyright protection signal such as SCMS or CGMS is added to the area, it is effectively avoided that the area is illegally processed and the copyright protection function is released. It is possible to appropriately exhibit a copyright protection function such as CGMS.
[0029]
FIG. 4 is a configuration diagram of the correlation detector 39 included in the determination unit 27.
The correlation detector 39 detects the correlation based on, for example, the SPOMF (Symmetric Phase Only Matched Filtering) method.
As shown in FIG. 4, the correlation detector 39 includes, for example, an FFT circuit (Fast Fourier Transform) 121, a whitening circuit 122, an FFT circuit 123, a whitening circuit 124, a complex conjugate circuit 125, a multiplication circuit 126, and an IFFT circuit 127. Have.
[0030]
For example, the FFT circuit 121 performs Fourier transform on the reproduction signal S6 input from the input unit 26 illustrated in FIG. 2 to generate first frequency component data S121, and outputs the first frequency component data S121 to the whitening circuit 122.
The whitening circuit 122 divides each complex number data constituting the first frequency component data S121 by the absolute value of each complex number data (that is, equalizes the absolute value of each element data), and the first complex number data S122. Is output to the multiplication circuit 126.
[0031]
For example, the FFT circuit 123 performs Fourier transform on the noise signal NOISE4 input from the noise filter 24 illustrated in FIG. 2 to generate second frequency component data S123, and the whitening circuit 124 generates second frequency component data. Each complex number data constituting S123 is divided by the absolute value of each complex number data to generate second complex number data S124, which is output to complex conjugate circuit 125.
[0032]
The complex conjugate circuit 125 generates the third complex number data S125 in which each complex number data constituting the second complex number data S124 is replaced with complex conjugate complex number data, and outputs this to the multiplication circuit 126.
The multiplication circuit 126 multiplies the first complex number data S122 and the third complex number data S125 to generate fourth complex number data S126, and outputs this to the IFFT circuit 127.
The IFFT circuit 127 performs inverse Fourier transform on the fourth complex number data S126 to generate correlation data S39.
Here, the correlation data S39 indicates all values obtained by correlating the relative positions of the reproduction signal S6 and the noise signal NOISE4 cyclically in two dimensions.
[0033]
In the above-described collation by SPOMF, the absolute value of each element is made equal after conversion to the frequency domain. For this reason, the correlation can be detected without being disturbed by the low-frequency signal of the image.
The correlation detector 39 based on the SPOMF having the configuration shown in FIG. 4 described above is very effective for image matching. This method is used for establishing synchronization in communication using spread spectrum, and is suitable for this method because synchronization can be established at a high speed by one calculation.
[0034]
When the determination signal S27 input from the determination unit 27 indicates “valid”, the control unit 28 continues to output the content signal CONT1 from the disc reading unit 21 to the output unit 22.
On the other hand, when the determination signal S27 input from the determination unit 27 indicates “not valid”, the control unit 28 stops the output of the content signal CONT1 from the disc reading unit 21 to the output unit 22.
[0035]
[Specific Configuration of Content Providing Device 2]
FIG. 5 is a configuration diagram of the content providing apparatus 2 shown in FIG.
As shown in FIG. 5, the content providing apparatus 2 includes, for example, a parameter / key specifying unit 12, a noise generating unit 13, a noise filter 14, an adding unit 15, a disc manufacturing unit 16, and a control unit 17.
The parameter / key specifying unit 12, the noise generating unit 13, the noise filter 14, the adding unit 15, the disk manufacturing unit 16, and the control unit 17 are, for example, secure modules that cannot monitor and tamper with internal processes and data from the outside. Is provided inside.
In the present embodiment, the content signal CONT may be read from a predetermined recording medium, or may be received via a network or the like.
[0036]
The parameter / key designating unit 12 designates the random number generating seed data SEED and encryption key data K_EN used for generating the noise signal to the noise generating unit 13.
Further, the parameter / key specifying unit 12 outputs the seed data SEED for generating random numbers and the key data K_EN for encryption to the disk manufacturing unit 16.
For example, the parameter / key designating unit 12 changes at least one of the seed data SEED for generating random numbers and the key data K_EN for encryption for each type of content signal CONT1 recorded on the recording disk DISK. specify.
[0037]
The noise generation unit 13 generates a random number based on the seed data SEED for random number generation designated by the parameter / key designation unit 12. Further, the noise generation unit 13 generates the noise signal NOISE 11 by encrypting the random number based on the designated encryption key data K_EN, and outputs the noise signal NOISE 11 to the noise filter 14.
The noise generation unit 13 has, for example, the same configuration as the noise generation unit 23 illustrated in FIG.
The noise filter 14 performs a filtering process on the noise signal NOISE 11 input from the noise generation unit 13 to generate a noise signal NOISE 1, and outputs this to the addition unit 15.
[0038]
The adding unit 15 adds (superimposes) the noise signal NOISE1 to the content signal CONT to generate the content signal CONT1, and outputs the content signal CONT1 to the disc manufacturing unit 16.
The disc manufacturing unit 16 records the content signal CONT1 input from the adding unit 15 on the recording disc DISK.
Further, the disc manufacturing unit 16 records the seed data SEED and the encryption key data K_EN input from the parameter / key designating unit 12 in a secure state in the recording disc DISK. For example, the disk manufacturing unit 16 encrypts the seed data SEED and the key data K_EN and records them in the disk manufacturing unit 16 or in a recording area that can be read in a secure state by the disk reading unit 21 of the content utilization device 11. By recording the seed data SEED and the key data K_EN, the recording in the secure state is realized.
For example, the control unit 17 executes a predetermined program and controls the operation of each component of the content providing apparatus 2 described above based on the execution of the program.
[0039]
In the signal processing system 1, as shown in FIG. 6, the content providing device 2 adds the noise signal NOISE1 of the content signal CONT to generate the content signal CONT1, and these are provided to the drive 7 via the recording disk DISK. The
Then, the drive 7 generates the noise signal NOISE4 using the seed data SEED and the key data K_EN used for generating the noise signal NOISE1, detects the correlation between the reproduction signal S6 and the noise signal NOISE4, and detects the content signal CONT1. And the validity of the recording disk DISK is determined.
[0040]
Hereinafter, an operation example of the signal processing system 1 shown in FIG. 1 will be described.
[Operation example of content providing apparatus 2]
FIG. 7 is a diagram for explaining an operation example of the content providing apparatus 2 shown in FIG.
Each step shown in FIG. 7 corresponds to the first step of the fifth invention, and the step of providing the recording disk DISK to the computer 3 corresponds to the second step of the fifth invention.
[0041]
Step ST1:
The parameter / key designating unit 12 designates the random number generating seed data SEED and encryption key data K_EN used for generating the noise signal to the noise generating unit 13.
Step ST2:
The PN generation units 31 and 33 and the multiplication unit 32 shown in FIG. 3 of the noise generation unit 13 generate the noise signal NOISE3 based on the random number generation seed data SEED specified in step ST1.
Then, the encryption unit 34 encrypts the noise signal NOISE3 based on the encryption key data K_EN designated in step ST1 to generate the noise signal NOISE11, and outputs this to the noise filter 14.
Then, the noise filter 14 performs a filtering process on the noise signal NOISE 11 input from the noise generation unit 13 to generate a noise signal NOISE 1, and outputs this to the addition unit 15.
[0042]
Step ST3:
The adding unit 15 adds (superimposes) the noise signal NOISE1 to the content signal CONT to generate the content signal CONT1, and outputs the content signal CONT1 to the disc manufacturing unit 16.
Step ST4:
The disc manufacturing unit 16 records the content signal CONT1 input from the adding unit 15 on the recording disc DISK.
Further, the disc manufacturing unit 16 records the seed data SEED and the encryption key data K_EN input from the parameter / key designating unit 12 in a secure state in the recording disc DISK.
[0043]
[Operation example of drive 7 of computer 3]
8 and 9 are flowcharts for explaining an operation example of the drive 7 of the computer 3 shown in FIG.
Step ST12 shown in FIG. 8 corresponds to the first process of the fourth invention, step ST13 corresponds to the second process of the fourth invention, and step ST14 corresponds to the third process of the fourth invention. Steps ST15 to ST20 correspond to the fourth step of the fourth invention.
Further, the process in which the reproducing unit 6 performs reproduction based on the reproduction signal output in step ST12 corresponds to the third process of the fifth invention, and steps ST15 to ST20 correspond to the fourth process of the fifth invention. It corresponds.
[0044]
Step ST11:
When the recording disk DISK manufactured by the content providing device 2 is set at the access position of the drive 7 of the computer 3, the disk reading unit 21 of the drive 7 reads the content signal CONT1 from the recording disk DISK.
Step ST12:
The disc reading unit 21 outputs the content signal CONT1 read in step ST11 from the output unit 22 to the reproduction unit 6 via the bus 11.
Step ST13:
In the reproduction unit 6, the reproduction process of the content signal CONT 1 is performed, and the reproduction signal S 6 is output from the reproduction unit 6 to the input unit 26 via the signal line 10.
Step ST14:
The disk reading unit 21 outputs the seed data SEED and the key data K_EN read from the recording disk DISK manufactured by the content providing device 2 in a secure state to the noise generation unit 23.
[0045]
Step ST15:
The noise generator 23 generates a random number based on the seed data SEED input from the disk reader 21. The noise generator 13 encrypts the random number based on the encryption key data K_EN input from the disk reader 21 to generate a noise signal NOISE 2 and outputs the noise signal NOISE 2 to the noise filter 24.
Step ST16:
The noise filter 24 performs a filtering process on the noise signal NOISE 2 input from the noise generation unit 23 to generate a noise signal NOISE 4, and outputs this to the determination unit 27.
[0046]
Step ST17:
The determination unit 27 detects a correlation between the noise signal NOISE4 from the noise filter 24 and the reproduction signal S6 input from the input unit 26 by the correlation detector 39.
Step ST18:
The determination unit 27 proceeds to step ST18 when the correlation detected in step ST17 is equal to or higher than a predetermined level, and proceeds to step ST19 otherwise.
[0047]
Step ST19:
The determination unit 27 determines that the content signal CONT1 is valid (the recording disc DISK has been obtained from the regular route) and that the content signal CONT1 has been properly reproduced. Is output to the control unit 28.
The control unit 28 continues to read the content signal CONT1 by the disc reading unit 21.
[0048]
Step ST20:
The determination unit 27 determines that the content signal CONT1 is not valid (the recording disc DISK is not obtained from a regular route) or that the content signal CONT1 is not properly reproduced, and so (not valid) Is output to the control unit 28.
The control unit 28 stops the reading of the content signal CONT1 by the disc reading unit 21.
[0049]
As described above, according to the computer 3, the drive 7 outputs the content signal CONT1 read from the recording disk DISK to the reproduction unit 6 and inputs the reproduction signal S6 from the reproduction unit 6.
Then, the drive 7 reads the seed data SEED and the key data K_EN recorded in a secure state on the recording disk DISK, the unique noise signal NOISE4 generated based on these, and the reproduction signal S6 input from the reproduction unit 6 Based on these correlations, the validity of the content signal CONT1 and whether or not the content signal CONT1 has been properly reproduced are verified.
For this reason, when an illegal program is executed in the CPU 4 and an illegal act of recording the content signal CONT1 output from the drive 7 on another recording medium without being played back by the playback unit 6, the playback signal S6 is sent to the drive 7. Is not input, and the illegal action can be detected by the reproducing unit 6, and the reading of the content signal CONT1 from the recording disk DISK can be stopped.
[0050]
Further, as described above, the computer 3 outputs the content signal CONT1 read from the recording disk DISK to the outside of the drive 7 on condition that the content signal CONT1 is appropriately reproduced in the reproducing unit 6. Therefore, the copyright protection function performed by the reproducing unit 6 based on the digital watermark information for copy control during reproduction can be appropriately exhibited.
[0051]
If the recording disk DISK is an illegal recording of the content signal CONT1, the seed data SEED and the key data K_EN are not recorded on the recording disk DISK. According to the computer 3, since the correlation between the noise signal NOISE4 and the reproduction signal S6 is detected in the drive 7 as described above, it can be determined whether or not the recording disk DISK is an illegal disk.
[0052]
Second embodiment
In the embodiment described above, the case where the drive 7 does not have the function of detecting the digital watermark information for copy control is exemplified. However, in addition to the function described in the first embodiment, the drive of the present embodiment It has a function of detecting digital watermark information for copy control.
In the present embodiment, as described in the first embodiment, digital watermark information for copy control is added to the content signal CONT1 by adding a predetermined change to the frequency component of the content signal CONT1 in a secret manner. Is added.
[0053]
FIG. 10 is a configuration diagram of the drive 7a of the present embodiment.
As illustrated in FIG. 10, the drive 7a includes, for example, a disk reading unit 21, an output unit 22, a noise generation unit 23, a noise filter 24, an input unit 26, a determination unit 27, a control unit 28a, and digital watermark information (CCWM) detection. Part 50.
Here, the digital watermark information detection unit 50 corresponds to the detection means of the first invention, and the control unit 28a corresponds to the control means of the first invention.
In FIG. 10, the constituent elements having the same reference numerals as those in FIG. 2 are the same as those described in the first embodiment.
The digital watermark information detection unit 50 detects the digital watermark information for copy control added to the reproduction signal S6 input from the reproduction unit 6, and outputs a detection signal S50 indicating the detection result to the control unit 28a.
In addition to the function of the control unit 28 described in the first embodiment, the control unit 28a has a copy control function for the content signal CONT1 based on the detection signal S50.
As described above, according to the drive 7a, in order to continue the reading operation of the content signal CONT1 by the disc reading unit 21, it is required to input the reproduction signal S6 appropriately, and the reproduction signal S6 includes electronic signals for copy control. Since watermark information is added, copy control can be realized by forcibly detecting the watermark information. Further, since this noise-based method itself can be used as video digital watermark information VWM or audio digital watermark information AWM, it can also be used in place of conventional VWM and AWM. In this case, since the detection circuit for copy control can also be used, there is an advantage that the circuit scale and processing can be reduced.
[0054]
In the content providing apparatus 2, the copy control digital watermark information is added to the content signal CONT1 so that the copy control digital watermark information added according to the position of the content signal CONT1 on the reproduction signal S6 changes. Then, information regarding the change pattern is recorded in a secure state on the recording disk DISK.
Then, the control unit 28a detects the change pattern of the digital watermark information for copy control in the reproduction signal S6 based on the detection signal S50 from the digital watermark information detection unit 50, and reads the change read from the recording disk DISK. By comparing with the information regarding the pattern, it is determined whether or not the reproduction signal S6 is a reproduction signal of the content signal CONT1 read from the recording disk DISK by the disk reading unit 21 immediately before.
As a result, when the reproduction signal S6 other than the content signal CONT1 read from the recording disk DISK is illegally input to the drive 7a, the control unit 28a can appropriately detect this, and the disc reading unit 21 The output of the content signal CONT1 can be stopped.
[0055]
Modified example of the second embodiment
FIG. 11 is a diagram for explaining a modification of the second embodiment shown in FIG.
In the second embodiment, when the computer 3a shown in FIG. 1 is a home server, in this embodiment, a drive (signal processing device) 7a of the home server is a network 10a such as an Ethernet (registered trademark) or a wireless network. To communicate with the terminal device 6a.
As shown in FIG. 11, the terminal device 6a receives the content signal CONT1 from the drive 7a shown in FIG. 10, decodes it by the decoding unit 81, and then expands it by the expansion unit 82 to generate a reproduction signal S6a. This is monitored by the monitor output unit 83.
The monitor output unit 83 transmits the reproduction signal S6a to the drive 7a via the network 10a.
In this case, the drive 7a may include a detection unit having a macrovision copy guard function in addition to the electronic watermark information detection unit 50 for copy control shown in FIG.
Further, in the content providing apparatus 2 of the second embodiment, the noise signal NOISE1 is intentionally low resistant so that the noise signal NOISE1 is lost or deformed by duplication or deformation processing or the like, and the noise signal NOISE1 is converted into the content signal CONT1. It may be added. Thereby, for example, when an unauthorized process such as falsification or deletion of copy control digital watermark information in the content signal CONT1 is performed, the correlation between the noise signal and the reproduction signal in the determination unit 27 becomes lower than the predetermined level. The output of the content signal CONT1 read from the recording disk DISK can be forcibly stopped.
[0056]
Third embodiment
This embodiment corresponds to the third invention.
In the first embodiment described above, the case where the noise generation unit 23, the noise filter 24, and the determination unit 27 are arranged inside the drive 7 is exemplified. However, in the present embodiment, these are arranged outside the drive 7. Will be explained.
FIG. 12 is a configuration diagram of the signal processing system 1b of the present embodiment.
In FIG. 12, the constituent elements having the same reference numerals as those in FIG. 1 are basically the same as those described in the first embodiment.
As illustrated in FIG. 12, the computer 3 b includes, for example, a CPU 4, a memory 5, a reproduction unit 6, a drive 7 b, and a determination unit 60 as illustrated in FIG. 12, and these are connected via the bus 11. .
In FIG. 12, the reproduction unit 6 corresponds to the reproduction unit of the third invention, the determination unit 60 corresponds to the determination unit of the third invention, and the drive 7b corresponds to the reception unit of the third invention.
[0057]
FIG. 13 is a configuration diagram of the drive 7b and the determination unit 60 shown in FIG.
As illustrated in FIG. 13, the drive 7 b includes, for example, a disk reading unit 21, an output unit 22, an input unit 23, a control unit 28, and an output unit 61.
Moreover, the determination part 60 has the noise production | generation part 23, the noise filter 24, the determination part 27, the input part 62, the input part 63, and the output part 64, for example.
In FIG. 13, components denoted by the same reference numerals as those in FIG. 2 are the same as those described in the first embodiment.
As shown in FIG. 13, in the computer 3b, the noise generation unit 23, the noise filter 24, and the determination unit 27 are arranged in the determination unit 60 outside the drive 7b.
[0058]
In the computer 3b, the seed data SEED and the key data K_EN read from the recording disk DISK by the disk reading unit 21 are input to the noise generation unit 23 in the determination unit 60 via the output unit 61 and the input unit 62.
Then, as described above, the noise generation unit 23 generates the noise signal NOISE2 based on the seed data SEED and the key data K_EN, and the noise signal NOISE4 is generated via the noise filter 24 and is output to the determination unit 27. .
[0059]
The disc reader 21 outputs the content signal CONT1 read from the recording disc DISK from the output unit 22 to the reproducing unit 6 via the bus 11.
Then, the reproduction signal S6 from the reproduction unit 6 is output to the determination unit 27 in the determination unit 60 via the signal line 10 and the input unit 63.
Then, as described above, the determination unit 27 detects the correlation between the noise signal NOISE4 from the noise filter 24 and the reproduction signal S6 from the input unit 63, and a determination signal S27 corresponding to the correlation is output from the output unit 64 and the input unit 64. The data is output to the control unit 28 of the drive 7b via the unit 23.
As described above, the control unit 28 controls the disk reading unit 21 based on the determination signal S27.
[0060]
The same effect as the computer 3 of the first embodiment can be obtained by the computer 3b of the present embodiment.
[0061]
Fourth embodiment
In the above-described embodiment, the seed data SEED and the key data K_EN are exemplified as “parameters received and held in a secure state” in the present invention, and the seed data SEED and key data K_EN are exemplified as “specific characteristics defined accordingly”. A case where a noise signal generated based on the key data K_EN is added to the content signal CONT1 is illustrated.
In the present embodiment, instead of the noise signal, for example, predetermined specific information such as digital watermark information is added by adding a predetermined change (modulation) to the frequency component of the content signal CONT1c in a secret manner. A case where the content signal CONT1c is added will be described.
The signal processing system 1c of this embodiment has the configuration shown in FIG. 1, and the drive 7c is different from the drive 7 of the first embodiment.
[0062]
FIG. 14 is a configuration diagram of the drive 7c of the present embodiment.
As illustrated in FIG. 14, the drive 7 c includes a disk reading unit 21 c, an output unit 22, an input unit 26, a determination unit 27 c, and a control unit 28.
In FIG. 14, the components given the same reference numerals as those in FIG. 2 are the same as those described in the first embodiment.
In the present embodiment, the content signal CONTc is recorded on the recording disc DISKc, and the parameter PARc is recorded in a secure state.
The parameter PARc indicates a value indicated by the digital watermark information added to the content signal CONT1c.
[0063]
In the drive 7c, the disk reading unit 21c reads the parameter PARc from the recording disk DISKc and outputs it to the determination unit 27c.
The determination unit 27c detects the digital watermark information added to the reproduction signal S6 input from the reproduction unit 6 via the signal line 10 and the input unit 26, the value indicated by the detected digital watermark information, and the disk reading unit It is determined whether or not the value indicated by the parameter PARc input from 21c matches. If the values match, a determination signal S27 indicating “valid” is output to the control unit 28; Is output to the control unit 28.
The control unit 28 continues to read the content signal CONT1c from the recording disk DISKc to the reproducing unit 6 when the determination signal S27 indicates “valid”, and from the recording disk DISKc when the determination signal S27 indicates “invalid”. Reading of the content signal CONT1c to the reproduction unit 6 is stopped.
[0064]
The present invention is not limited to the embodiment described above.
[First Modification]
In the above-described embodiment, the case where the parameters such as the seed data SEED and the key data K_EN and the content signal CONT are provided to the signal processing device such as the drive via the package medium such as the recording disk DISK is exemplified. If it is provided in a secure state to a signal processing device such as a drive, the content signal and parameters may be provided to the signal processing device such as a drive via another medium such as a network.
That is, instead of the drive 7 or the like of the computer 3, a receiving apparatus that receives a content signal or the like via broadcasting or a network may be used.
Also, some of the components such as the drive 7 may be realized by a program or the like.
[0065]
[Second Modification]
In the first embodiment and the like described above, at least one of the seed data SEED and the key data K_EN is specific to the recording disk DISK or the content signal CONT1, and the noise generation unit 13 shown in FIG. The case where the noise signal NOISE11 (NOISE1) is generated and added to the content signal CONT1 is illustrated.
In addition, the present invention also divides the frequency band of the content signal CONT1, adds predetermined digital watermark information (signal) in a unique combination to each frequency band, and uses the combination pattern as a parameter in a secure recording disk. You may record on DISK.
In this case, the drive 7 or the like detects whether digital watermark information is added in the combination pattern in the reproduction signal S6 based on the parameters read from the recording disk DISK.
[0066]
In the present invention, digital watermark information selected by a unique combination among a plurality of digital watermark information may be added to the content signal CONT1, and the combination pattern may be recorded as a parameter on the recording disk DISK in a secure state. .
Also in this case, the drive 7 or the like detects whether the electronic watermark information is added in the combination pattern in the reproduction signal S6 based on the parameters read from the recording disk DISK.
Further, the present invention adds an international management code of music software such as an ISCR (International Standard Recording Code) corresponding to the content to the content signal CONT1 as digital watermark information, and detects it by the drive 7 or the like. Also good.
In this case, for example, digital watermark information obtained by encrypting a management code such as ISCR with a predetermined scramble key is added to the content signal CONT1. The scramble key is recorded in a secure state on the recording disk DISK as a parameter together with the ISCR.
[0067]
[Third Modification]
In the present invention, a random number or the like may be used as the digital watermark information described above. A plurality of random numbers may be used in combination.
Further, a noise signal and digital watermark information obtained based on the identification data ID such as the content signal CONT1 and the recording disk DISK are added to the content signal CONT1 and the like, and the identification data ID is used as a parameter and recorded on the recording disk DISK in a secure state. Even in this case, the present invention can be applied. In this case, the unique ID can be managed on the drive side. For example, if a list of illegal IDs discovered in the past is stored safely from a new disk or online, the unique ID that has been illegally used is directly restricted on the drive side. It becomes possible to eliminate by doing.
In the present invention, for example, parameters corresponding to the seed data SEED or the key data K_EN of the first embodiment are arranged in a unique ID, a copy control bit, etc., and this is encrypted with a unique key. A noise signal NOISE2 may be generated in the noise generator 23 shown in FIG.
In this case, for example, the control unit 28 controls the output of the content signal CONT1 based on the copy control bit.
In addition, for example, when an operation such as copying the content signal CONT1 to another recording medium is performed, that is, when the use of the content signal CONT1 is performed, the control unit 28 depends on the usage form. The copy control bit may be rewritten. This can prevent unlimited copies of private copies. Further, the control unit 28 may set the copy control bit to copy-free or never-copy if necessary.
[Fourth Modification]
In the above-described embodiment, the case where the drive 7 or the like reads the content signal CONT1 from the recording disk DISK is illustrated, but the drive 7b or the like may further have a function of writing a new content signal to the recording disk DISK. .
In this case, the drive 7 or the like generates a parameter such as seed data SEED or key data K_EN specific to the content signal to be written as necessary, and has a characteristic specific to the parameter in the content signal to be written. Make it.
[0068]
[Fifth Modification]
In the embodiment described above, video or audio is exemplified as the content signal CONT1, but the content signal CONT1 may be data other than video and audio.
When the content signal CONT1 includes both a video signal and an audio signal, the noise signal NOISE1 may be added to one of the video signal and the audio signal, and the digital watermark information for copy control may be added to the other. .
Further, both the noise signal NOISE1 and the digital watermark information for copy control may be added to either one of the video signal and the audio signal.
The drive 7 and the like detect them based on the above-described noise signal and additional pattern of digital watermark information.
[0069]
【The invention's effect】
ADVANTAGE OF THE INVENTION According to this invention, the signal processing apparatus which can determine the correctness of a content signal, and whether the content signal was reproduced | regenerated appropriately, its method, and a computer can be provided.
[Brief description of the drawings]
FIG. 1 is an overall configuration diagram of a signal processing system 1 according to a first embodiment of the present invention.
FIG. 2 is a configuration diagram of the drive shown in FIG. 1;
FIG. 3 is a configuration diagram of a noise generation unit shown in FIG. 2;
FIG. 4 is a configuration diagram of the correlation detector shown in FIG. 2;
FIG. 5 is a configuration diagram of the content providing apparatus shown in FIG. 1;
6 is a diagram for explaining determination processing in the signal processing system shown in FIG. 1. FIG.
FIG. 7 is a flowchart for explaining an operation example of the content providing apparatus shown in FIG. 5;
8 is a flowchart for explaining an operation example of the drive shown in FIG. 2; FIG.
9 is a continuation flowchart of FIG. 8 for explaining an operation example of the drive shown in FIG. 2;
FIG. 10 is a configuration diagram of a drive 7 according to the second embodiment of this invention.
FIG. 11 is a diagram for explaining a modification of the second embodiment of the present invention.
FIG. 12 is a configuration diagram of a computer according to a third embodiment of this invention.
FIG. 13 is a configuration diagram of the drive and computer shown in FIG. 12;
FIG. 14 is a configuration diagram of a drive according to a fourth embodiment of the present invention.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1, 1a, 1b, 1c ... Signal processing system, 2 ... Content provision apparatus, 3, 3a ... Computer, 4 ... CPU, 5 ... Memory, 6 ... Playback part, 7, 7a, 7b ... Drive, 10 ... Signal line, DESCRIPTION OF SYMBOLS 11 ... Bus, 21 ... Disc reading part, 22 ... Output part, 23 ... Noise generation part, 24 ... Noise filter, 26 ... Input part, 27 ... Determination part, 39 ... Correlation detector, 31, 33 ... PN generation part, 34 ... Cryptographic part

Claims (13)

An output means for outputting the provided content signal;
An input means for inputting a signal;
An acquisition means for acquiring parameters in a secure state;
The characteristics that are defined according to the parameters acquired by the acquisition means, and the characteristics that should be possessed by the reproduction signal obtained by reproducing the content signal when the content signal output by the output means is valid, A signal processing apparatus comprising: determination means for determining whether or not the signal input by the input means has. When the signal input by the input unit has the characteristic, the determination unit reproduces the received content signal and the content signal output by the output unit is reproduced. The signal processing apparatus according to claim 1, wherein the signal processing apparatus determines that it has been. The determination means generates an additional signal based on the parameter by a predetermined method, detects a correlation between the generated additional signal and the signal input by the input means, and based on the detected correlation. The signal processing apparatus according to claim 1, wherein the signal input by the input unit determines whether the signal has the characteristic. Detection means for detecting a control signal for copy control added to the content signal detected by reproduction of the content signal from the signal input by the input means;
The signal processing apparatus according to claim 1, further comprising a control unit that performs copy control of the content signal based on a detection result of the detection unit. The determination unit obtains information on a change pattern of the control signal for copy control in the provided content signal in a secure state, and based on the detection result of the detection unit, the acquired change pattern 5. The signal processing device according to claim 4, wherein the signal processing device detects whether or not the detected control signal exists in the detected control signal, and performs the determination using the detection result. An access means for reading the parameters and the content signal from the recording medium in a state where the recording medium for recording the content signal and recording the parameter in a secure state is set at a predetermined access position;
The determination means performs the determination based on the parameter read from the recording medium by the access means,
The signal processing apparatus according to claim 1, wherein the output unit outputs the content signal read from the recording medium by the access unit. The control unit according to claim 1, further comprising a control unit that stops the output of the content signal from the output unit when the determination unit determines that the signal input by the input unit does not have the characteristic. Signal processing device. The parameter has a value specific to the content signal or a recording medium used to provide the content signal,
2. The determination unit according to claim 1, wherein the determination unit determines whether the signal input by the input unit has the specific characteristic defined in accordance with the parameter acquired by the acquisition unit. Signal processing device. The determination means is disposed in a secure state inside the drive of the computer,
The output means outputs the content signal from the drive so as to secure the inside of the drive,
The signal processing apparatus according to claim 1, wherein the input unit inputs the signal into the drive so as to secure the inside of the drive. Receiving means for receiving the content signal;
Reproduction means for reproducing the content signal to generate a reproduction signal or attachment means for attaching the reproduction means;
A computer having processing means for executing a predetermined program,
The receiving means is
Output means for outputting the provided content signal to the reproduction means;
Input means for inputting the reproduction signal from the reproduction means;
An acquisition means for acquiring parameters in a secure state;
The characteristics that are defined according to the parameters acquired by the acquisition means, and the characteristics that should be possessed by the reproduction signal obtained by reproducing the content signal when the content signal output by the output means is valid, And a determination unit that determines whether or not the reproduction signal input by the input unit has. Reproduction means for reproducing a content signal and generating a reproduction signal, or attachment means for attaching the reproduction means;
When the reproduction signal input from the reproduction means has characteristics defined according to a predetermined parameter and should have a reproduction signal obtained by reproducing the content signal when the content signal is valid Determination means for determining whether or not to have;
And a receiving unit that receives the content signal, outputs the content signal to the reproduction unit, receives a predetermined parameter in a secure state, and outputs the parameter to the determination unit. A signal processing method executed by a signal processing device,
A first step of outputting the provided content signal to the outside of the signal processing device;
A second step of inputting a signal from outside the signal processing device;
A third step of acquiring parameters in a secure state;
A reproduction signal obtained by reproducing the content signal when the content signal output in the first step is valid and has characteristics defined according to the parameter acquired in the third step And a fourth step of determining whether or not the signal input in the second step has a power characteristic. A first step in which the content providing device generates a content signal having characteristics according to a predetermined parameter;
A second step in which the content providing device provides the parameter to the computer in a secure state and provides the content signal generated in the first step to the computer;
A third step in which the computer reproduces the content signal received in the second step;
A characteristic defined by the computer according to the parameter received in the second step, and a characteristic that a reproduction signal obtained by reproducing the content signal when the content signal is valid should have And a fifth step of determining whether or not the signal obtained by the reproduction of the third step has.

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